Effect of local thermoplasmonic heating on biological membranes

Guillermo S. Moreno-Pescador; Iliriana Qoqaj; Victoria Thusgaard Ruhoff; Josephine Iversen; Jesper Nylandsted; Poul Martin Bendix

doi:10.1117/12.2530154

Effect of local thermoplasmonic heating on biological membranes

Guillermo S. Moreno-Pescador, Iliriana Qoqaj, Victoria Thusgaard Ruhoff, Josephine Iversen, Jesper Nylandsted, Poul Martin Bendix

1 Citationer (Scopus)

Abstract

Optical trapping of plasmonic nanoparticles for controlled nanoscopic damage of cellular plasma membranes can be used to gain deeper insight into the role of plasma membrane repair proteins. Here we present a synthetic platform of giant unilamellar vesicles (GUVs) in the vicinity of trapped nanoplasmonic particles as a proposed model assay to characterize the permeability of a damaged GUV membrane, i.e. size of an inflicted hole. Water soluble fluorescent molecules with different sizes are used to characterize the extent of the membrane lesion since their differential permeability will provide information about the size of the rupture. We find that trapped gold nanoparticles can create substantial holes, observed via the discriminating influx of various sized molecules across the membrane. The technique, yet unrefined, provides groundwork for future investigations of annexin repair proteins, using nanoscopic heating of plasmonic particles to create quantifiable membrane damage.

Originalsprog	Engelsk
Artikelnummer	110830M
Tidsskrift	Proceedings of S P I E - International Society for Optical Engineering
Vol/bind	11083
Antal sider	19
ISSN	0277-786X
DOI	https://doi.org/10.1117/12.2530154
Status	Udgivet - 9 sep. 2019

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10.1117/12.2530154

Citationsformater

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title = "Effect of local thermoplasmonic heating on biological membranes",

abstract = "Optical trapping of plasmonic nanoparticles for controlled nanoscopic damage of cellular plasma membranes can be used to gain deeper insight into the role of plasma membrane repair proteins. Here we present a synthetic platform of giant unilamellar vesicles (GUVs) in the vicinity of trapped nanoplasmonic particles as a proposed model assay to characterize the permeability of a damaged GUV membrane, i.e. size of an inflicted hole. Water soluble fluorescent molecules with different sizes are used to characterize the extent of the membrane lesion since their differential permeability will provide information about the size of the rupture. We find that trapped gold nanoparticles can create substantial holes, observed via the discriminating influx of various sized molecules across the membrane. The technique, yet unrefined, provides groundwork for future investigations of annexin repair proteins, using nanoscopic heating of plasmonic particles to create quantifiable membrane damage.",

author = "Moreno-Pescador, {Guillermo S.} and Iliriana Qoqaj and {Thusgaard Ruhoff}, Victoria and Josephine Iversen and Jesper Nylandsted and Bendix, {Poul Martin}",

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AU - Moreno-Pescador, Guillermo S.

AU - Qoqaj, Iliriana

AU - Thusgaard Ruhoff, Victoria

AU - Iversen, Josephine

AU - Nylandsted, Jesper

AU - Bendix, Poul Martin

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N2 - Optical trapping of plasmonic nanoparticles for controlled nanoscopic damage of cellular plasma membranes can be used to gain deeper insight into the role of plasma membrane repair proteins. Here we present a synthetic platform of giant unilamellar vesicles (GUVs) in the vicinity of trapped nanoplasmonic particles as a proposed model assay to characterize the permeability of a damaged GUV membrane, i.e. size of an inflicted hole. Water soluble fluorescent molecules with different sizes are used to characterize the extent of the membrane lesion since their differential permeability will provide information about the size of the rupture. We find that trapped gold nanoparticles can create substantial holes, observed via the discriminating influx of various sized molecules across the membrane. The technique, yet unrefined, provides groundwork for future investigations of annexin repair proteins, using nanoscopic heating of plasmonic particles to create quantifiable membrane damage.

AB - Optical trapping of plasmonic nanoparticles for controlled nanoscopic damage of cellular plasma membranes can be used to gain deeper insight into the role of plasma membrane repair proteins. Here we present a synthetic platform of giant unilamellar vesicles (GUVs) in the vicinity of trapped nanoplasmonic particles as a proposed model assay to characterize the permeability of a damaged GUV membrane, i.e. size of an inflicted hole. Water soluble fluorescent molecules with different sizes are used to characterize the extent of the membrane lesion since their differential permeability will provide information about the size of the rupture. We find that trapped gold nanoparticles can create substantial holes, observed via the discriminating influx of various sized molecules across the membrane. The technique, yet unrefined, provides groundwork for future investigations of annexin repair proteins, using nanoscopic heating of plasmonic particles to create quantifiable membrane damage.

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DO - 10.1117/12.2530154

M3 - Conference article

SN - 0277-786X

VL - 11083

JO - Proceedings of SPIE - The International Society for Optical Engineering

JF - Proceedings of SPIE - The International Society for Optical Engineering

M1 - 110830M

ER -

Effect of local thermoplasmonic heating on biological membranes

Abstract

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